#    This file is part of Metasm, the Ruby assembly manipulation suite
#    Copyright (C) 2006-2009 Yoann GUILLOT
#
#    Licence is LGPL, see LICENCE in the top-level directory


require 'metasm/main'
require 'metasm/parse_c'

module Metasm
module C
	class Parser
		def precompile
			@toplevel.precompile(Compiler.new(self, @program))
			self
		end
	end

	# each CPU defines a subclass of this one
	class Compiler
		# an ExeFormat (mostly used for unique label creation, and cpu.check_reserved_name)
		attr_accessor :exeformat
		# the C Parser (destroyed by compilation)
		attr_accessor :parser
		# an array of assembler statements (strings)
		attr_accessor :source
		# list of unique labels generated (to recognize user-defined ones)
		attr_accessor :auto_label_list
		# map asm name -> original C name (for exports etc)
		attr_accessor :label_oldname

		attr_accessor :curexpr
		# allows 'raise self' (eg struct.offsetof)
		def exception(msg='EOF unexpected')
			ParseError.new "near #@curexpr: #{msg}"
		end

		# creates a new CCompiler from an ExeFormat and a C Parser
		def initialize(parser, exeformat=nil, source=[])
			exeformat ||= ExeFormat.new
			@parser, @exeformat, @source = parser, exeformat, source
			@auto_label_list = {}
			@label_oldname = {}
		end

		def new_label(base='')
			lbl = @exeformat.new_label base
			@auto_label_list[lbl] = true
			lbl
		end

		def toplevel ; @parser.toplevel end
		def typesize ; @parser.typesize end
		def sizeof(*a) @parser.sizeof(*a) end

		# compiles the c parser toplevel to assembler statements in self.source (::Array of ::String)
		#
		# starts by precompiling parser.toplevel (destructively):
		# static symbols are converted to toplevel ones, as nested functions
		# uses an ExeFormat (the argument) to create unique label/variable names
		#
		# remove typedefs/enums
		# CExpressions: all expr types are converted to __int8/__int16/__int32/__int64 (sign kept) (incl. ptr), + void
		#  struct member dereference/array indexes are converted to *(ptr + off)
		#  coma are converted to 2 statements, ?: are converted to If
		#  :|| and :&& are converted to If + assignment to temporary
		#  immediate quotedstrings/floats are converted to references to const static toplevel
		#  postincrements are replaced by a temporary (XXX arglist)
		#  compound statements are unnested
		# Asm are kept (TODO precompile clobber types)
		# Declarations: initializers are converted to separate assignment CExpressions
		# Blocks are kept unless empty
		# structure dereferences/array indexing are converted to *(ptr + offset)
		# While/For/DoWhile/Switch are converted to If/Goto
		# Continue/Break are converted to Goto
		# Cases are converted to Labels during Switch conversion
		# Label statements are removed
		# Return: 'return <foo>;' => 'return <foo>; goto <end_of_func>;', 'return;' => 'goto <eof>;'
		# If: 'if (a) b; else c;' => 'if (a) goto l1; { c; }; goto l2; l1: { b; } l2:'
		#  && and || in condition are expanded to multiple If
		# functions returning struct are precompiled (in Declaration/CExpression/Return)
		#
		# in a second phase, unused labels are removed from functions, as noop goto (goto x; x:)
		# dead code is removed ('goto foo; bar; baz:' => 'goto foo; baz:') (TODO)
		#
		# after that, toplevel is no longer valid C (bad types, blocks moved...)
		#
		# then toplevel statements are sorted (.text, .data, .rodata, .bss) and compiled into asm statements in self.source
		#
		# returns the asm source in a single string
		def compile
			cf = @exeformat.unique_labels_cache.keys & @auto_label_list.keys
			raise "compile_c name conflict: #{cf.inspect}" if not cf.empty?
			@exeformat.unique_labels_cache.update @auto_label_list

			@parser.toplevel.precompile(self)

			# reorder statements (arrays of Variables) following exe section typical order
			funcs, rwdata, rodata, udata = [], [], [], []
			@parser.toplevel.statements.each { |st|
				if st.kind_of? Asm
					@source << st.body
					next
				end
				raise 'non-declaration at toplevel! ' + st.inspect if not st.kind_of? Declaration
				v = st.var
				if v.type.kind_of? Function
					funcs << v if v.initializer	# no initializer == storage :extern
				elsif v.storage == :extern
				elsif v.initializer
					if v.type.qualifier.to_a.include?(:const) or
					(v.type.kind_of? Array and v.type.type.qualifier.to_a.include?(:const))
						rodata << v
					else
						rwdata << v
					end
				else
					udata << v
				end
			}

			if not funcs.empty?
				@exeformat.compile_setsection @source, '.text'
				funcs.each { |func| c_function(func) }
				c_program_epilog
			end

			align = 1
			if not rwdata.empty?
				@exeformat.compile_setsection @source, '.data'
				rwdata.each { |data| align = c_idata(data, align) }
			end

			if not rodata.empty?
				@exeformat.compile_setsection @source, '.rodata'
				rodata.each { |data| align = c_idata(data, align) }
			end

			if not udata.empty?
				@exeformat.compile_setsection @source, '.bss'
				udata.each  { |data| align = c_udata(data, align) }
			end

			# needed to allow asm parser to use our autogenerated label names
			@exeformat.unique_labels_cache.delete_if { |k, v| @auto_label_list[k] }

			@source.join("\n")
		end

		# compiles a C function +func+ to asm source into the array of strings +str+
		# in a first pass the stack variable offsets are computed,
		# then each statement is compiled in turn
		def c_function(func)
			# must wait the Declaration to run the CExpr for dynamic auto offsets,
			# and must run those statements once only
			# TODO alloc a stack variable to maintain the size for each dynamic array
			# TODO offset of arguments
			# TODO nested function
			c_init_state(func)

			# hide the full @source while compiling, then add prolog/epilog (saves 1 pass)
			@source << ''
			@source << "#{@label_oldname[func.name]}:" if @label_oldname[func.name]
			@source << "#{func.name}:"
			presource, @source = @source, []

			c_block(func.initializer)

			tmpsource, @source = @source, presource
			c_prolog
			@source.concat tmpsource
			c_epilog
			@source << ''
		end

		def c_block(blk)
			c_block_enter(blk)
			blk.statements.each { |stmt|
				case stmt
				when CExpression; c_cexpr(stmt)
				when Declaration; c_decl(stmt.var)
				when If; c_ifgoto(stmt.test, stmt.bthen.target)
				when Goto; c_goto(stmt.target)
				when Label; c_label(stmt.name)
				when Return; c_return(stmt.value)
				when Asm; c_asm(stmt)
				when Block; c_block(stmt)
				else raise
				end
			}
			c_block_exit(blk)
		end

		def c_block_enter(blk)
		end

		def c_block_exit(blk)
		end

		def c_label(name)
			@source << "#{name}:"
		end

		# fills @state.offset (empty hash)
		# automatic variable => stack offset, (recursive)
		# offset is an ::Integer or a CExpression (dynamic array)
		# assumes offset 0 is a ptr-size-aligned address
		# TODO registerize automatic variables
		def c_reserve_stack(block, off = 0)
			block.statements.each { |stmt|
				case stmt
				when Declaration
					next if stmt.var.type.kind_of? Function
					off = c_reserve_stack_var(stmt.var, off)
					@state.offset[stmt.var] = off
				when Block
					c_reserve_stack(stmt, off)
					# do not update off, not nested subblocks can overlap
				end
			}
		end

		# computes the new stack offset for var
		# off is either an offset from stack start (:ptr-size-aligned) or
		#  a CExpression [[[expr, +, 7], &, -7], +, off]
		def c_reserve_stack_var(var, off)
			if (arr_type = var.type).kind_of? Array and (arr_sz = arr_type.length).kind_of? CExpression
				# dynamic array !
				arr_sz = CExpression.new(arr_sz, :*, sizeof(nil, arr_type.type),
					       BaseType.new(:long, :unsigned)).precompile_inner(@parser, nil)
				off = CExpression.new(arr_sz, :+, off, arr_sz.type)
				off = CExpression.new(off, :+,  7, off.type)
				off = CExpression.new(off, :&, -7, off.type)
				CExpression.new(off, :+,  0, off.type)
			else
				al = var.type.align(@parser)
				sz = sizeof(var)
				case off
				when CExpression; CExpression.new(off.lexpr, :+, ((off.rexpr + sz + al - 1) / al * al), off.type)
				else (off + sz + al - 1) / al * al
				end
			end
		end

		# here you can add thing like stubs for PIC code
		def c_program_epilog
		end

		# compiles a C static data definition into an asm string
		# returns the new alignment value
		def c_idata(data, align)
			w = data.type.align(@parser)
			@source << ".align #{align = w}" if w > align

			@source << "#{@label_oldname[data.name]}:" if @label_oldname[data.name]
			@source << data.name.dup
			len = c_idata_inner(data.type, data.initializer)
			len %= w
			len == 0 ? w : len
		end

		# dumps an anonymous variable definition, appending to the last line of source
		# source.last is a label name or is empty before calling here
		# return the length of the data written
		def c_idata_inner(type, value)
			case type
			when BaseType
				value ||= 0

				if type.name == :void
					@source.last << ':' if not @source.last.empty?
					return 0
				end

				@source.last <<
				case type.name
				when :__int8;  ' db '
				when :__int16; ' dw '
				when :__int32; ' dd '
				when :__int64; ' dq '
				when :ptr; " d#{%w[x b w x d x x x q][@parser.typesize[type.name]]} "
				when :float;   ' db ' + [value].pack(@parser.endianness == :little ? 'e' : 'g').unpack('C*').join(', ') + ' // '
				when :double;  ' db ' + [value].pack(@parser.endianness == :little ? 'E' : 'G').unpack('C*').join(', ') + ' // '
				when :longdouble; ' db ' + [value].pack(@parser.endianness == :little ? 'E' : 'G').unpack('C*').join(', ') + ' // '	# XXX same as :double
				else raise "unknown idata type #{type.inspect} #{value.inspect}"
				end

				@source.last << c_idata_inner_cexpr(value)

				@parser.typesize[type.name]

			when Struct
				value ||= []
				@source.last << ':' if not @source.last.empty?
				# could .align here, but if there is our label name just before, it should have been .aligned too..
				raise "unknown struct initializer #{value.inspect}" if not value.kind_of? ::Array
				sz = 0
				type.members.zip(value).each { |m, v|
					if m.name and wsz = type.offsetof(@parser, m.name) and sz < wsz
						@source << "db #{wsz-sz} dup(?)"
					end
					@source << ''
					flen = c_idata_inner(m.type, v)
					sz += flen
				}

				sz

			when Union
				value ||= []
				@source.last << ':' if not @source.last.empty?
				len = sizeof(nil, type)
				raise "unknown union initializer #{value.inspect}" if not value.kind_of? ::Array
				idx = value.rindex(value.compact.last) || 0
				raise "empty union initializer" if not idx
				wlen = c_idata_inner(type.members[idx].type, value[idx])
				@source << "db #{'0' * (len - wlen) * ', '}" if wlen < len

				len

			when Array
				value ||= []
				if value.kind_of? CExpression and not value.op and value.rexpr.kind_of? ::String
					elen = sizeof(nil, value.type.type)
					@source.last <<
					case elen
					when 1; ' db '
					when 2; ' dw '
					else raise 'bad char* type ' + value.inspect
					end << value.rexpr.inspect

					len = type.length || (value.rexpr.length+1)
					if len > value.rexpr.length
						@source.last << (', 0' * (len - value.rexpr.length))
					end

					elen * len

				elsif value.kind_of? ::Array
					@source.last << ':' if not @source.last.empty?
					len = type.length || value.length
					value.each { |v|
						@source << ''
						c_idata_inner(type.type, v)
					}
					len -= value.length
					if len > 0
						@source << " db #{len * sizeof(nil, type.type)} dup(0)"
					end

					sizeof(nil, type.type) * len

				else raise "unknown static array initializer #{value.inspect}"
				end
			end
		end

		def c_idata_inner_cexpr(expr)
			expr = expr.reduce(@parser) if expr.kind_of? CExpression
			case expr
			when ::Integer; (expr >= 4096) ? ('0x%X' % expr) : expr.to_s
			when ::Numeric; expr.to_s
			when Variable
				case expr.type
				when Array; expr.name
				else c_idata_inner_cexpr(expr.initializer)
				end
			when CExpression
				if not expr.lexpr
					case expr.op
					when :&
						case expr.rexpr
						when Variable; expr.rexpr.name
						else raise 'unhandled addrof in initializer ' + expr.rexpr.inspect
						end
					#when :*
					when :+; c_idata_inner_cexpr(expr.rexpr)
					when :-; ' -' << c_idata_inner_cexpr(expr.rexpr)
					when nil
						e = c_idata_inner_cexpr(expr.rexpr)
						if expr.rexpr.kind_of? CExpression
							e = '(' << e << " & 0#{'ff'*sizeof(expr)}h)"
						end
						e
					else raise 'unhandled initializer expr ' + expr.inspect
					end
				else
					case expr.op
					when :+, :-, :*, :/, :%, :<<, :>>, :&, :|, :^
						e = '(' << c_idata_inner_cexpr(expr.lexpr) <<
						expr.op.to_s << c_idata_inner_cexpr(expr.rexpr) << ')'
						if expr.type.integral?
							# db are unsigned
							e = '(' << e << " & 0#{'ff'*sizeof(expr)}h)"
						end
						e
					#when :'.'
					#when :'->'
					#when :'[]'
					else raise 'unhandled initializer expr ' + expr.inspect
					end
				end
			else raise 'unhandled initializer ' + expr.inspect
			end
		end

		def c_udata(data, align)
			@source << "#{@label_oldname[data.name]}:" if @label_oldname[data.name]
			@source << "#{data.name} "
			@source.last <<
			case data.type
			when BaseType
				len = @parser.typesize[data.type.name]
				case data.type.name
				when :__int8;  'db ?'
				when :__int16; 'dw ?'
				when :__int32; 'dd ?'
				when :__int64; 'dq ?'
				else "db #{len} dup(?)"
				end
			else
				len = sizeof(data)
				"db #{len} dup(?)"
			end
			len %= align
			len == 0 ? align : len
		end

		# return non-nil if the variable name is unsuitable to appear as is in the asm listing
		# eg filter out asm instruction names
		def check_reserved_name(var)
			return true if @exeformat.cpu and @exeformat.cpu.check_reserved_name(var.name)
			%w[db dw dd dq].include?(var.name)
		end
	end

	class Statement
		# all Statements/Declaration must define a precompile(compiler, scope) method
		# it must append itself to scope.statements

		# turns a statement into a new block
		def precompile_make_block(scope)
			b = Block.new scope
			b.statements << self
			b
		end
	end

	class Block
		# precompile all statements, then simplifies symbols/structs types
		def precompile(compiler, scope=nil)
			stmts = @statements.dup
			@statements.clear
			stmts.each { |st|
				compiler.curexpr = st
				st.precompile(compiler, self)
			}

			# cleanup declarations
			@symbol.delete_if { |n, s| not s.kind_of? Variable }
			@struct.delete_if { |n, s| not s.kind_of? Union }
			@symbol.each_value { |var|
				CExpression.precompile_type(compiler, self, var, true)
			}
			@struct.each_value { |var|
				next if not var.members
				var.members.each { |m|
					CExpression.precompile_type(compiler, self, m, true)
				}
			}
			scope.statements << self if scope and not @statements.empty?
		end

		# removes unused labels, and in-place goto (goto toto; toto:)
		def precompile_optimize
			list = []
			precompile_optimize_inner(list, 1)
			precompile_optimize_inner(list, 2)
		end

		# step 1: list used labels/unused goto
		# step 2: remove unused labels
		def precompile_optimize_inner(list, step)
			lastgoto = nil
			hadref = false
			walk = lambda { |expr|
				next if not expr.kind_of? CExpression
				# gcc's unary && support
				if not expr.op and not expr.lexpr and expr.rexpr.kind_of? Label
					list << expr.rexpr.name
				else
					walk[expr.lexpr]
					if expr.rexpr.kind_of? ::Array
						expr.rexpr.each { |r| walk[r] }
					else
						walk[expr.rexpr]
					end
				end
			}
			@statements.dup.each { |s|
				lastgoto = nil if not s.kind_of? Label
				case s
				when Block
					s.precompile_optimize_inner(list, step)
					@statements.delete s if step == 2 and s.statements.empty?
				when CExpression; walk[s] if step == 1
				when Label
					case step
					when 1
						if lastgoto and lastgoto.target == s.name
							list << lastgoto
							list.delete s.name if not hadref
						end
					when 2; @statements.delete s if not list.include? s.name
					end
				when Goto, If
					s.kind_of?(If) ? g = s.bthen : g = s
					case step
					when 1
						hadref = list.include? g.target
						lastgoto = g
						list << g.target
					when 2
						if list.include? g
							idx = @statements.index s
							@statements.delete s
							@statements[idx, 0] = s.test if s != g and not s.test.constant?
						end
					end
				end
			}
			list
		end

		# noop
		def precompile_make_block(scope) self end

		def continue_label ; defined?(@continue_label) ? @continue_label : @outer.continue_label end
		def continue_label=(l) @continue_label = l end
		def break_label ; defined?(@break_label) ? @break_label : @outer.break_label end
		def break_label=(l) @break_label = l end
		def return_label ; defined?(@return_label) ? @return_label : @outer.return_label end
		def return_label=(l) @return_label = l end
		def nonauto_label=(l) @nonauto_label = l end
		def nonauto_label ; defined?(@nonauto_label) ? @nonauto_label : @outer.nonauto_label end
		def function ; defined?(@function) ? @function : @outer.function end
		def function=(f) @function = f end
	end

	class Declaration
		def precompile(compiler, scope)
			if (@var.type.kind_of? Function and @var.initializer and scope != compiler.toplevel) or @var.storage == :static or compiler.check_reserved_name(@var)
				old = @var.name
				ref = scope.symbol.delete old
				if scope == compiler.toplevel or (@var.type.kind_of?(Function) and not @var.initializer)
					if n = compiler.label_oldname.index(old)
						# reuse same name as predeclarations
						@var.name = n
					else
						newname = old
						newname = compiler.new_label newname until newname != old
						if not compiler.check_reserved_name(@var)
							compiler.label_oldname[newname] = old
						end
						@var.name = newname
					end
					ref ||= scope.symbol[@var.name] || @var
					# append only one actual declaration for all predecls (the one with init, or the last uninit)
					scope.statements << self if ref.eql?(@var)
				else
					@var.name = compiler.new_label @var.name until @var.name != old
					compiler.toplevel.statements << self
				end
				compiler.toplevel.symbol[@var.name] = ref
			else
				scope.symbol[@var.name] ||= @var
				appendme = true if scope.symbol[@var.name].eql?(@var)
			end

			if i = @var.initializer
				if @var.type.kind_of? Function
					if @var.type.type.kind_of? Union
						s = @var.type.type
						v = Variable.new
						v.name = compiler.new_label('return_struct_ptr')
						v.type = Pointer.new(s)
						CExpression.precompile_type(compiler, scope, v)
						@var.type.args.unshift v
						@var.type.type = v.type
					end
					i.function = @var
					i.return_label = compiler.new_label('epilog')
					i.nonauto_label = {}
					i.precompile(compiler)
					Label.new(i.return_label).precompile(compiler, i)
					i.precompile_optimize
					# append now so that static dependencies are declared before us
					# TODO no pure inline if addrof(func) needed
					scope.statements << self if appendme and not @var.attributes.to_a.include? 'inline'
				elsif scope != compiler.toplevel and @var.storage != :static
					scope.statements << self if appendme
					Declaration.precompile_dyn_initializer(compiler, scope, @var, @var.type, i)
					@var.initializer = nil
				else
					scope.statements << self if appendme
					@var.initializer = Declaration.precompile_static_initializer(compiler, @var.type, i)
				end
			else
				scope.statements << self if appendme
			end
		end

		# turns an initializer to CExpressions in scope.statements
		def self.precompile_dyn_initializer(compiler, scope, var, type, init)
			case type = type.untypedef
			when Array
				# XXX TODO type.length may be dynamic !!
				case init
				when CExpression
					# char toto[] = "42"
					if not init.kind_of? CExpression or init.op or init.lexpr or not init.rexpr.kind_of? ::String
						raise "unknown initializer #{init.inspect} for #{var.inspect}"
					end
					init = init.rexpr.unpack('C*') + [0]
					init.map! { |chr| CExpression.new(nil, nil, chr, type.type) }
					precompile_dyn_initializer(compiler, scope, var, type, init)

				when ::Array
					type.length ||= init.length
					# len is an Integer
					init.each_with_index { |it, idx|
						next if not it
						break if idx >= type.length
						idx = CExpression.new(nil, nil, idx, BaseType.new(:long, :unsigned))
						v = CExpression.new(var, :'[]', idx, type.type)
						precompile_dyn_initializer(compiler, scope, v, type.type, it)
					}
				else raise "unknown initializer #{init.inspect} for #{var.inspect}"
				end
			when Union
				case init
				when CExpression, Variable
					if init.type.untypedef.kind_of? BaseType
						# works for struct foo bar[] = {0}; ...
						type.members.each { |m|
							v = CExpression.new(var, :'.', m.name, m.type)
							precompile_dyn_initializer(compiler, scope, v, v.type, init)
						}
					elsif init.type.untypedef.kind_of? type.class
						CExpression.new(var, :'=', init, type).precompile(compiler, scope)
					else
						raise "bad initializer #{init.inspect} for #{var.inspect}"
					end
				when ::Array
					init.each_with_index{ |it, idx|
						next if not it
						m = type.members[idx]
						v = CExpression.new(var, :'.', m.name, m.type)
						precompile_dyn_initializer(compiler, scope, v, m.type, it)
					}
				else raise "unknown initializer #{init.inspect} for #{var.inspect}"
				end
			else
				case init
				when CExpression
					CExpression.new(var, :'=', init, type).precompile(compiler, scope)
				else raise "unknown initializer #{init.inspect} for #{var.inspect}"
				end
			end
		end

		# returns a precompiled static initializer (eg string constants)
		def self.precompile_static_initializer(compiler, type, init)
			# TODO
			case type = type.untypedef
			when Array
				if init.kind_of? ::Array
					init.map { |i| precompile_static_initializer(compiler, type.type, i) }
				else
					init
				end
			when Union
				if init.kind_of? ::Array
					init.zip(type.members).map { |i, m| precompile_static_initializer(compiler, m.type, i) }
				else
					init
				end
			else
				if init.kind_of? CExpression and init = init.reduce(compiler) and init.kind_of? CExpression
					if not init.op and init.rexpr.kind_of? ::String
						v = Variable.new
						v.storage = :static
						v.name = 'char_' + init.rexpr.gsub(/[^a-zA-Z]/, '')[0, 8]
						v.type = Array.new(type.type)
						v.type.length = init.rexpr.length + 1
						v.type.type.qualifier = [:const]
						v.initializer = CExpression.new(nil, nil, init.rexpr, type)
						Declaration.new(v).precompile(compiler, compiler.toplevel)
						init.rexpr = v
					end
					init.rexpr = precompile_static_initializer(compiler, init.rexpr.type, init.rexpr) if init.rexpr.kind_of? CExpression
					init.lexpr = precompile_static_initializer(compiler, init.lexpr.type, init.lexpr) if init.lexpr.kind_of? CExpression
				end
				init
			end
		end
	end

	class If
		def precompile(compiler, scope)
			expr = lambda { |e| e.kind_of?(CExpression) ? e : CExpression.new(nil, nil, e, e.type) }

			if @bthen.kind_of? Goto or @bthen.kind_of? Break or @bthen.kind_of? Continue
				# if () goto l; else b; => if () goto l; b;
				if belse
					t1 = @belse
					@belse = nil
				end

				# need to convert user-defined Goto target !
				@bthen.precompile(compiler, scope)
				@bthen = scope.statements.pop	# break => goto break_label
			elsif belse
				# if () a; else b; => if () goto then; b; goto end; then: a; end:
				t1 = @belse
				t2 = @bthen
				l2 = compiler.new_label('if_then')
				@bthen = Goto.new(l2)
				@belse = nil
				l3 = compiler.new_label('if_end')
			else
				# if () a; => if (!) goto end; a; end:
				t1 = @bthen
				l2 = compiler.new_label('if_end')
				@bthen = Goto.new(l2)
				@test = CExpression.negate(@test)
			end

			@test = expr[@test]
			case @test.op
			when :'&&'
				# if (c1 && c2) goto a; => if (!c1) goto b; if (c2) goto a; b:
				l1 = compiler.new_label('if_nand')
				If.new(CExpression.negate(@test.lexpr), Goto.new(l1)).precompile(compiler, scope)
				@test = expr[@test.rexpr]
				precompile(compiler, scope)
			when :'||'
				l1 = compiler.new_label('if_or')
				If.new(expr[@test.lexpr], Goto.new(@bthen.target)).precompile(compiler, scope)
				@test = expr[@test.rexpr]
				precompile(compiler, scope)
			else
				@test = CExpression.precompile_inner(compiler, scope, @test)
				t = @test.reduce(compiler)
				if t.kind_of? ::Integer
					if t == 0
						Label.new(l1, nil).precompile(compiler, scope) if l1
						t1.precompile(compiler, scope) if t1
						Label.new(l2, nil).precompile(compiler, scope) if l2
						Label.new(l3, nil).precompile(compiler, scope) if l3
					else
						scope.statements << @bthen
						Label.new(l1, nil).precompile(compiler, scope) if l1
						Label.new(l2, nil).precompile(compiler, scope) if l2
						t2.precompile(compiler, scope) if t2
						Label.new(l3, nil).precompile(compiler, scope) if l3
					end
					return
				end
				scope.statements << self
			end

			Label.new(l1, nil).precompile(compiler, scope) if l1
			t1.precompile(compiler, scope) if t1
			Goto.new(l3).precompile(compiler, scope) if l3
			Label.new(l2, nil).precompile(compiler, scope) if l2
			t2.precompile(compiler, scope) if t2
			Label.new(l3, nil).precompile(compiler, scope) if l3
		end
	end

	class For
		def precompile(compiler, scope)
			if init
				@init.precompile(compiler, scope)
				scope = @init if @init.kind_of? Block
			end

			@body = @body.precompile_make_block scope
			@body.continue_label = compiler.new_label 'for_continue'
			@body.break_label = compiler.new_label 'for_break'
			label_test = compiler.new_label 'for_test'

			Label.new(label_test).precompile(compiler, scope)
			if test
				If.new(CExpression.negate(@test), Goto.new(@body.break_label)).precompile(compiler, scope)
			end

			@body.precompile(compiler, scope)

			Label.new(@body.continue_label).precompile(compiler, scope)
			if iter
				@iter.precompile(compiler, scope)
			end

			Goto.new(label_test).precompile(compiler, scope)
			Label.new(@body.break_label).precompile(compiler, scope)
		end
	end

	class While
		def precompile(compiler, scope)
			@body = @body.precompile_make_block scope
			@body.continue_label = compiler.new_label('while_continue')
			@body.break_label = compiler.new_label('while_break')

			Label.new(@body.continue_label).precompile(compiler, scope)

			If.new(CExpression.negate(@test), Goto.new(@body.break_label)).precompile(compiler, scope)

			@body.precompile(compiler, scope)

			Goto.new(@body.continue_label).precompile(compiler, scope)
			Label.new(@body.break_label).precompile(compiler, scope)
		end
	end

	class DoWhile
		def precompile(compiler, scope)
			@body = @body.precompile_make_block scope
			@body.continue_label = compiler.new_label('dowhile_continue')
			@body.break_label = compiler.new_label('dowhile_break')
			loop_start = compiler.new_label('dowhile_start')

			Label.new(loop_start).precompile(compiler, scope)

			@body.precompile(compiler, scope)

			Label.new(@body.continue_label).precompile(compiler, scope)

			If.new(@test, Goto.new(loop_start)).precompile(compiler, scope)

			Label.new(@body.break_label).precompile(compiler, scope)
		end
	end

	class Switch
		def precompile(compiler, scope)
			var = Variable.new
			var.storage = :register
			var.name = compiler.new_label('switch')
			var.type = @test.type
			var.initializer = @test
			CExpression.precompile_type(compiler, scope, var)
			Declaration.new(var).precompile(compiler, scope)

			@body = @body.precompile_make_block scope
			@body.break_label = compiler.new_label('switch_break')
			@body.precompile(compiler)
			default = @body.break_label
			# recursive lambda to change Case to Labels
			# dynamically creates the If sequence
			walk = lambda { |blk|
				blk.statements.each_with_index { |s, i|
					case s
					when Case
						label = compiler.new_label('case')
						if s.expr == 'default'
							default = label
						elsif s.exprup
							If.new(CExpression.new(CExpression.new(var, :'>=', s.expr, BaseType.new(:int)), :'&&',
										CExpression.new(var, :'<=', s.exprup, BaseType.new(:int)),
										BaseType.new(:int)), Goto.new(label)).precompile(compiler, scope)
						else
							If.new(CExpression.new(var, :'==', s.expr, BaseType.new(:int)),
								Goto.new(label)).precompile(compiler, scope)
						end
						blk.statements[i] = Label.new(label)
					when Block
						walk[s]
					end
				}
			}
			walk[@body]
			Goto.new(default).precompile(compiler, scope)
			scope.statements << @body
			Label.new(@body.break_label).precompile(compiler, scope)
		end
	end

	class Continue
		def precompile(compiler, scope)
			Goto.new(scope.continue_label).precompile(compiler, scope)
		end
	end

	class Break
		def precompile(compiler, scope)
			Goto.new(scope.break_label).precompile(compiler, scope)
		end
	end

	class Return
		def precompile(compiler, scope)
			if @value
				@value = CExpression.new(nil, nil, @value, @value.type) if not @value.kind_of? CExpression
				if @value.type.untypedef.kind_of? Union
					@value = @value.precompile_inner(compiler, scope)
					func = scope.function.type
					CExpression.new(CExpression.new(nil, :*, func.args.first, @value.type), :'=', @value, @value.type).precompile(compiler, scope)
					@value = func.args.first
				else
					# cast to function return type
					@value = CExpression.new(nil, nil, @value, scope.function.type.type).precompile_inner(compiler, scope)
				end
				scope.statements << self
			end
			Goto.new(scope.return_label).precompile(compiler, scope)
		end
	end

	class Label
		def precompile(compiler, scope)
			if name and (not compiler.auto_label_list[@name])
				@name = scope.nonauto_label[@name] ||= compiler.new_label(@name)
			end
			scope.statements << self
			if statement
				@statement.precompile(compiler, scope)
				@statement = nil
			end
		end
	end

	class Case
		def precompile(compiler, scope)
			@expr = CExpression.precompile_inner(compiler, scope, @expr)
			@exprup = CExpression.precompile_inner(compiler, scope, @exprup) if exprup
			super(compiler, scope)
		end
	end

	class Goto
		def precompile(compiler, scope)
			if not compiler.auto_label_list[@target]
				@target = scope.nonauto_label[@target] ||= compiler.new_label(@target)
			end
			scope.statements << self
		end
	end

	class Asm
		def precompile(compiler, scope)
			scope.statements << self
			# TODO CExpr.precompile_type(clobbers)
		end
	end

	class CExpression
		def precompile(compiler, scope)
			i = precompile_inner(compiler, scope, false)
			scope.statements << i if i
		end

		# changes obj.type to a precompiled type
		# keeps struct/union, change everything else to __int\d
		# except Arrays if declaration is true (need to know variable allocation sizes etc)
		# returns the type
		def self.precompile_type(compiler, scope, obj, declaration = false)
			case t = obj.type.untypedef
			when BaseType
				case t.name
				when :void
				when :float, :double, :longdouble
				else t = BaseType.new("__int#{compiler.typesize[t.name]*8}".to_sym, t.specifier)
				end
			when Array
				if declaration; precompile_type(compiler, scope, t, declaration)
				else   t = BaseType.new("__int#{compiler.typesize[:ptr]*8}".to_sym, :unsigned)
				end
			when Pointer
				if t.type.untypedef.kind_of? Function
					precompile_type(compiler, scope, t, declaration)
				else
					t = BaseType.new("__int#{compiler.typesize[:ptr]*8}".to_sym, :unsigned)
				end
			when Enum;     t = BaseType.new("__int#{compiler.typesize[:int]*8}".to_sym)
			when Function
				precompile_type(compiler, scope, t)
				t.args ||= []
				t.args.each { |a| precompile_type(compiler, scope, a) }
			when Union
				if declaration and t.members and not t.name	# anonymous struct
					t.members.each { |a| precompile_type(compiler, scope, a, true) }
				end
			else raise 'bad type ' + t.inspect
			end
			(t.qualifier  ||= []).concat obj.type.qualifier  if obj.type.qualifier  and t != obj.type
			(t.attributes ||= []).concat obj.type.attributes if obj.type.attributes and t != obj.type
			while obj.type.kind_of? TypeDef
				obj.type = obj.type.type
				(t.qualifier  ||= []).concat obj.type.qualifier  if obj.type.qualifier  and t != obj.type
				(t.attributes ||= []).concat obj.type.attributes if obj.type.attributes and t != obj.type
			end
			obj.type = t
		end

		def self.precompile_inner(compiler, scope, expr, nested = true)
			case expr
			when CExpression; expr.precompile_inner(compiler, scope, nested)
			else expr
			end
		end

		# returns a new CExpression with simplified self.type, computes structure offsets
		# turns char[]/float immediates to reference to anonymised const
		# TODO 'a = b += c' => 'b += c; a = b' (use nested argument)
		# TODO handle precompile_inner return nil
		# TODO struct.bits
		def precompile_inner(compiler, scope, nested = true)
			case @op
			when :'.'
				# a.b => (&a)->b
				lexpr = CExpression.precompile_inner(compiler, scope, @lexpr)
				ll = lexpr
				ll = lexpr.rexpr while ll.kind_of? CExpression and not ll.op
				if ll.kind_of? CExpression and ll.op == :'*' and not ll.lexpr
					# do not change lexpr.rexpr.type directly to a pointer, might retrigger (ptr+imm) => (ptr + imm*sizeof(*ptr))
					@lexpr = CExpression.new(nil, nil, ll.rexpr, Pointer.new(lexpr.type))
				else
					@lexpr = CExpression.new(nil, :'&', lexpr, Pointer.new(lexpr.type))
				end
				@op = :'->'
				precompile_inner(compiler, scope)
			when :'->'
				# a->b => *(a + off(b))
				struct = @lexpr.type.untypedef.type.untypedef
				lexpr = CExpression.precompile_inner(compiler, scope, @lexpr)
				@lexpr = nil
				@op = nil
				if struct.kind_of? Union and (off = struct.offsetof(compiler, @rexpr)) != 0
					off = CExpression.new(nil, nil, off, BaseType.new(:int, :unsigned))
					@rexpr = CExpression.new(lexpr, :'+', off, lexpr.type)
					# ensure the (ptr + value) is not expanded to (ptr + value * sizeof(*ptr))
					CExpression.precompile_type(compiler, scope, @rexpr)
				else
					# union or 1st struct member
					@rexpr = lexpr
				end
				if @type.kind_of? Array # Array member type is already an address
				else
					@rexpr = CExpression.new(nil, :*, @rexpr, @rexpr.type)
				end
				precompile_inner(compiler, scope)
			when :'[]'
				rexpr = CExpression.precompile_inner(compiler, scope, @rexpr)
				if rexpr.kind_of? CExpression and not rexpr.op and rexpr.rexpr == 0
					@rexpr = @lexpr
				else
					@rexpr = CExpression.new(@lexpr, :'+', rexpr, @lexpr.type)
				end
				@op = :'*'
				@lexpr = nil
				precompile_inner(compiler, scope)
			when :'?:'
				# cannot precompile in place, a conditionnal expression may have a coma: must turn into If
				if @lexpr.kind_of? CExpression
					@lexpr = @lexpr.precompile_inner(compiler, scope)
					if not @lexpr.lexpr and not @lexpr.op and @lexpr.rexpr.kind_of? ::Numeric
						if @lexpr.rexpr == 0
							e = @rexpr[1]
						else
							e = @rexpr[0]
						end
						e = CExpression.new(nil, nil, e, e.type) if not e.kind_of? CExpression
						return e.precompile_inner(compiler, scope)
					end
				end
				raise 'conditional in toplevel' if scope == compiler.toplevel	# just in case
				var = Variable.new
				var.storage = :register
				var.name = compiler.new_label('ternary')
				var.type = @rexpr[0].type
				CExpression.precompile_type(compiler, scope, var)
				Declaration.new(var).precompile(compiler, scope)
				If.new(@lexpr, CExpression.new(var, :'=', @rexpr[0], var.type), CExpression.new(var, :'=', @rexpr[1], var.type)).precompile(compiler, scope)
				@lexpr = nil
				@op = nil
				@rexpr = var
				precompile_inner(compiler, scope)
			when :'&&'
				if scope == compiler.toplevel
					@lexpr = CExpression.precompile_inner(compiler, scope, @lexpr)
					@rexpr = CExpression.precompile_inner(compiler, scope, @rexpr)
					CExpression.precompile_type(compiler, scope, self)
					self
				else
					var = Variable.new
					var.storage = :register
					var.name = compiler.new_label('and')
					var.type = @type
					CExpression.precompile_type(compiler, scope, var)
					var.initializer = CExpression.new(nil, nil, 0, var.type)
					Declaration.new(var).precompile(compiler, scope)
					l = @lexpr.kind_of?(CExpression) ? @lexpr : CExpression.new(nil, nil, @lexpr, @lexpr.type)
					r = @rexpr.kind_of?(CExpression) ? @rexpr : CExpression.new(nil, nil, @rexpr, @rexpr.type)
					If.new(l, If.new(r, CExpression.new(var, :'=', CExpression.new(nil, nil, 1, var.type), var.type))).precompile(compiler, scope)
					@lexpr = nil
					@op = nil
					@rexpr = var
					precompile_inner(compiler, scope)
				end
			when :'||'
				if scope == compiler.toplevel
					@lexpr = CExpression.precompile_inner(compiler, scope, @lexpr)
					@rexpr = CExpression.precompile_inner(compiler, scope, @rexpr)
					CExpression.precompile_type(compiler, scope, self)
					self
				else
					var = Variable.new
					var.storage = :register
					var.name = compiler.new_label('or')
					var.type = @type
					CExpression.precompile_type(compiler, scope, var)
					var.initializer = CExpression.new(nil, nil, 1, var.type)
					Declaration.new(var).precompile(compiler, scope)
					l = @lexpr.kind_of?(CExpression) ? @lexpr : CExpression.new(nil, nil, @lexpr, @lexpr.type)
					l = CExpression.new(nil, :'!', l, var.type)
					r = @rexpr.kind_of?(CExpression) ? @rexpr : CExpression.new(nil, nil, @rexpr, @rexpr.type)
					r = CExpression.new(nil, :'!', r, var.type)
					If.new(l, If.new(r, CExpression.new(var, :'=', CExpression.new(nil, nil, 0, var.type), var.type))).precompile(compiler, scope)
					@lexpr = nil
					@op = nil
					@rexpr = var
					precompile_inner(compiler, scope)
				end
			when :funcall
				if @lexpr.kind_of? Variable and @lexpr.type.kind_of? Function and @lexpr.attributes and @lexpr.attributes.include? 'inline' and @lexpr.initializer
					# TODO check recursive call (direct or indirect)
					raise 'inline varargs unsupported' if @lexpr.type.varargs
					rtype = @lexpr.type.type.untypedef
					if not rtype.kind_of? BaseType or rtype.name != :void
						rval = Variable.new
						rval.name = compiler.new_label('inline_return')
						rval.type = @lexpr.type.type
						Declaration.new(rval).precompile(compiler, scope)
					end
					inline_label = {}
					locals = @lexpr.type.args.zip(@rexpr).inject({}) { |h, (fa, a)|
						h.update fa => CExpression.new(nil, nil, a, fa.type).precompile_inner(compiler, scope)
					}
					copy_inline_ce = lambda { |ce|
						case ce
						when CExpression; CExpression.new(copy_inline_ce[ce.lexpr], ce.op, copy_inline_ce[ce.rexpr], ce.type)
						when Variable; locals[ce] || ce
						when ::Array; ce.map { |e_| copy_inline_ce[e_] }
						else ce
						end
					}
					copy_inline = lambda { |stmt, scp|
						case stmt
						when Block
							b = Block.new(scp)
							stmt.statements.each { |s|
								s = copy_inline[s, b]
								b.statements << s if s
							}
							b
						when If;     If.new(copy_inline_ce[stmt.test], copy_inline[stmt.bthen, scp])		# re-precompile ?
						when Label;  Label.new(inline_label[stmt.name]  ||= compiler.new_label('inline_'+stmt.name))
						when Goto;   Goto.new(inline_label[stmt.target] ||= compiler.new_label('inline_'+stmt.target))
						when Return; CExpression.new(rval, :'=', copy_inline_ce[stmt.value], rval.type).precompile_inner(compiler, scp) if stmt.value
						when CExpression; copy_inline_ce[stmt]
						when Declaration
							nv = stmt.var.dup
							if nv.type.kind_of? Array and nv.type.length.kind_of? CExpression
								nv.type = Array.new(nv.type.type, copy_inline_ce[nv.type.length])	# XXX nested dynamic?
							end
							locals[stmt.var] = nv
							scp.symbol[nv.name] = nv
							Declaration.new(nv)
						else raise 'unexpected inline statement ' + stmt.inspect
						end
					}
					scope.statements << copy_inline[@lexpr.initializer, scope]		# body already precompiled
					CExpression.new(nil, nil, rval, rval.type).precompile_inner(compiler, scope)
				elsif @type.kind_of? Union
					var = Variable.new
					var.name = compiler.new_label('return_struct')
					var.type = @type
					Declaration.new(var).precompile(compiler, scope)
					@rexpr.unshift CExpression.new(nil, :&, var, Pointer.new(var.type))

					var2 = Variable.new
					var2.name = compiler.new_label('return_struct_ptr')
					var2.type = Pointer.new(@type)
					var2.storage = :register
					CExpression.precompile_type(compiler, scope, var2)
					Declaration.new(var2).precompile(compiler, scope)
					@type = var2.type
					CExpression.new(var2, :'=', self, var2.type).precompile(compiler, scope)

					CExpression.new(nil, :'*', var2, var.type).precompile_inner(compiler, scope)
				else
					t = @lexpr.type.untypedef
					t = t.type.untypedef if t.pointer?
					@lexpr = CExpression.precompile_inner(compiler, scope, @lexpr)
					types = t.args.map { |a| a.type }
					# cast args to func prototype
					@rexpr.map! { |e_| (types.empty? ? e_ : CExpression.new(nil, nil, e_, types.shift)).precompile_inner(compiler, scope) }
					CExpression.precompile_type(compiler, scope, self)
					self
				end
			when :','
				lexpr = @lexpr.kind_of?(CExpression) ? @lexpr : CExpression.new(nil, nil, @lexpr, @lexpr.type)
				rexpr = @rexpr.kind_of?(CExpression) ? @rexpr : CExpression.new(nil, nil, @rexpr, @rexpr.type)
				lexpr.precompile(compiler, scope)
				rexpr.precompile_inner(compiler, scope)
			when :'!'
				CExpression.precompile_type(compiler, scope, self)
				if @rexpr.kind_of?(CExpression)
					case @rexpr.op
					when :'<', :'>', :'<=', :'>=', :'==', :'!='
						@op = { :'<' => :'>=', :'>' => :'<=', :'<=' => :'>', :'>=' => :'<',
							:'==' => :'!=', :'!=' => :'==' }[@rexpr.op]
						@lexpr = @rexpr.lexpr
						@rexpr = @rexpr.rexpr
						precompile_inner(compiler, scope)
					when :'&&', :'||'
						@op = { :'&&' => :'||', :'||' => :'&&' }[@rexpr.op]
						@lexpr = CExpression.new(nil, :'!', @rexpr.lexpr, @type)
						@rexpr = CExpression.new(nil, :'!', @rexpr.rexpr, @type)
						precompile_inner(compiler, scope)
					when :'!'
						if @rexpr.rexpr.kind_of? CExpression
							@op = nil
							@rexpr = @rexpr.rexpr
						else
							@op = :'!='
							@lexpr = @rexpr.rexpr
							@rexpr = CExpression.new(nil, nil, 0, @lexpr.type)
						end
						precompile_inner(compiler, scope)
					else
						@rexpr = CExpression.precompile_inner(compiler, scope, @rexpr)
						self
					end
				else
					@rexpr = CExpression.precompile_inner(compiler, scope, @rexpr)
					self
				end
			when :'++', :'--'
				if not @rexpr
					var = Variable.new
					var.storage = :register
					var.name = compiler.new_label('postincrement')
					var.type = @type
					Declaration.new(var).precompile(compiler, scope)
					CExpression.new(var, :'=', @lexpr, @type).precompile(compiler, scope)
					CExpression.new(nil, @op, @lexpr, @type).precompile(compiler, scope)
					@lexpr = nil
					@op = nil
					@rexpr = var
					precompile_inner(compiler, scope)
				elsif @type.pointer? and compiler.sizeof(nil, @type.untypedef.type.untypedef) != 1
					# ++ptr => ptr += sizeof(*ptr) (done in += precompiler)
					@op = { :'++' => :'+=', :'--' => :'-=' }[@op]
					@lexpr = @rexpr
					@rexpr = CExpression.new(nil, nil, 1, BaseType.new(:ptr, :unsigned))
					precompile_inner(compiler, scope)
				else
					CExpression.precompile_type(compiler, scope, self)
					@rexpr = CExpression.precompile_inner(compiler, scope, @rexpr)
					self
				end
			when :'='
				# handle structure assignment/array assignment
				case @lexpr.type.untypedef
				when Union
					# rexpr may be a :funcall
					@rexpr = CExpression.precompile_inner(compiler, scope, @rexpr)
					@lexpr.type.untypedef.members.zip(@rexpr.type.untypedef.members) { |m1, m2|
						# assume m1 and m2 are compatible
						v1 = CExpression.new(@lexpr, :'.', m1.name, m1.type)
						v2 = CExpression.new(@rexpr, :'.', m2.name, m1.type)
						CExpression.new(v1, :'=', v2, v1.type).precompile(compiler, scope)
					}
					# (foo = bar).toto
					@op = nil
					@rexpr = @lexpr
					@lexpr = nil
					@type = @rexpr.type
					precompile_inner(compiler, scope) if nested
				when Array
					if not len = @lexpr.type.untypedef.length
						@rexpr = CExpression.precompile_inner(compiler, scope, @rexpr)
						# char toto[] = "bla"
						if @rexpr.kind_of? CExpression and not @rexpr.lexpr and not @rexpr.op and
								@rexpr.rexpr.kind_of? Variable and @rexpr.rexpr.type.kind_of? Array
							len = @rexpr.rexpr.type.length
						end
					end
					raise 'array initializer with no length !' if not len
					# TODO optimize...
					len.times { |i|
						i = CExpression.new(nil, nil, i, BaseType.new(:long, :unsigned))
						v1 = CExpression.new(@lexpr, :'[]', i, @lexpr.type.untypedef.type)
						v2 = CExpression.new(@rexpr, :'[]', i, v1.type)
						CExpression.new(v1, :'=', v2, v1.type).precompile(compiler, scope)
					}
					@op = nil
					@rexpr = @lexpr
					@lexpr = nil
					@type = @rexpr.type
					precompile_inner(compiler, scope) if nested
				else
					@lexpr = CExpression.precompile_inner(compiler, scope, @lexpr)
					@rexpr = CExpression.precompile_inner(compiler, scope, @rexpr)
					CExpression.precompile_type(compiler, scope, self)
					self
				end
			when nil
				case @rexpr
				when Block
					# compound statements
					raise 'compound statement in toplevel' if scope == compiler.toplevel	# just in case
					var = Variable.new
					var.storage = :register
					var.name = compiler.new_label('compoundstatement')
					var.type = @type
					CExpression.precompile_type(compiler, scope, var)
					Declaration.new(var).precompile(compiler, scope)
					if @rexpr.statements.last.kind_of? CExpression
						@rexpr.statements[-1] = CExpression.new(var, :'=', @rexpr.statements[-1], var.type)
						@rexpr.precompile(compiler, scope)
					end
					@rexpr = var
					precompile_inner(compiler, scope)
				when ::String
					# char[] immediate
					v = Variable.new
					v.storage = :static
					v.name = 'char_' + @rexpr.tr('^a-zA-Z', '')[0, 8]
					v.type = Array.new(@type.type)
					v.type.length = @rexpr.length + 1
					v.type.type.qualifier = [:const]
					v.initializer = CExpression.new(nil, nil, @rexpr, @type)
					Declaration.new(v).precompile(compiler, scope)
					@rexpr = v
					precompile_inner(compiler, scope)
				when ::Float
					# float immediate
					v = Variable.new
					v.storage = :static
					v.name = @type.untypedef.name.to_s
					v.type = @type
					v.type.qualifier = [:const]
					v.initializer = CExpression.new(nil, nil, @rexpr, @type)
					Declaration.new(v).precompile(compiler, scope)
					@rexpr = CExpression.new(nil, :'*', v, v.type)
					precompile_inner(compiler, scope)
				when CExpression
					# simplify casts
					CExpression.precompile_type(compiler, scope, self)
					# propagate type first so that __uint64 foo() { return -1 } => 0xffffffffffffffff
					@rexpr.type = @type if @rexpr.kind_of? CExpression and @rexpr.op == :- and not @rexpr.lexpr and @type.kind_of? BaseType and @type.name == :__int64	# XXX kill me
					@rexpr = @rexpr.precompile_inner(compiler, scope)
					if @type.kind_of? BaseType and @rexpr.type.kind_of? BaseType
						if @rexpr.type == @type
							# noop cast
							@lexpr, @op, @rexpr = @rexpr.lexpr, @rexpr.op, @rexpr.rexpr
						elsif not @rexpr.op and @type.integral? and @rexpr.type.integral?
							if @rexpr.rexpr.kind_of? ::Numeric and (val = reduce(compiler)).kind_of? ::Numeric
								@rexpr = val
							elsif compiler.typesize[@type.name] < compiler.typesize[@rexpr.type.name]
								# (char)(short)(int)(long)foo => (char)foo
								@rexpr = @rexpr.rexpr
							end
						end
					end
					self
				else
					CExpression.precompile_type(compiler, scope, self)
					self
				end
			else
				# int+ptr => ptr+int
				if @op == :+ and @lexpr and @lexpr.type.integral? and @rexpr.type.pointer?
					@rexpr, @lexpr = @lexpr, @rexpr
				end

				# handle pointer + 2 == ((char *)pointer) + 2*sizeof(*pointer)
				if @rexpr and [:'+', :'+=', :'-', :'-='].include? @op and
						@type.pointer? and @rexpr.type.integral?
					sz = compiler.sizeof(nil, @type.untypedef.type.untypedef)
					if sz != 1
						sz = CExpression.new(nil, nil, sz, @rexpr.type)
						@rexpr = CExpression.new(@rexpr, :'*', sz, @rexpr.type)
					end
				end

				# type promotion => cast
				case @op
				when :+, :-, :*, :/, :&, :|, :^, :%
				    if @lexpr
					if @lexpr.type != @type
						@lexpr = CExpression.new(nil, nil, @lexpr, @lexpr.type) if not @lexpr.kind_of? CExpression
						@lexpr = CExpression.new(nil, nil, @lexpr, @type)
					end
					if @rexpr.type != @type
						@rexpr = CExpression.new(nil, nil, @rexpr, @rexpr.type) if not @rexpr.kind_of? CExpression
						@rexpr = CExpression.new(nil, nil, @rexpr, @type)
					end
				    end
				when :>>, :<<
					# char => int
					if @lexpr.type != @type
						@lexpr = CExpression.new(nil, nil, @lexpr, @lexpr.type) if not @lexpr.kind_of? CExpression
						@lexpr = CExpression.new(nil, nil, @lexpr, @type)
					end
				when :'+=', :'-=', :'*=', :'/=', :'&=', :'|=', :'^=', :'%='
					if @rexpr.type != @lexpr.type
						@rexpr = CExpression.new(nil, nil, @rexpr, @rexpr.type) if not @rexpr.kind_of? CExpression
						@rexpr = CExpression.new(nil, nil, @rexpr, @type)
					end
				end

				@lexpr = CExpression.precompile_inner(compiler, scope, @lexpr)
				@rexpr = CExpression.precompile_inner(compiler, scope, @rexpr)

				if @op == :'&' and not @lexpr
					rr = @rexpr
					rr = rr.rexpr while rr.kind_of? CExpression and not rr.op
					if rr.kind_of? CExpression and rr.op == :'*' and not rr.lexpr
						@lexpr = nil
						@op = nil
						@rexpr = rr.rexpr
						return precompile_inner(compiler, scope)
					elsif rr != @rexpr
						@rexpr = rr
						return precompile_inner(compiler, scope)
					end
				end

				CExpression.precompile_type(compiler, scope, self)

				isnumeric = lambda { |e_| e_.kind_of?(::Numeric) or (e_.kind_of? CExpression and
					not e_.lexpr and not e_.op and e_.rexpr.kind_of? ::Numeric) }

				# calc numeric
				# XXX do not simplify operations involving variables (for type overflow etc)
				if isnumeric[@rexpr] and (not @lexpr or isnumeric[@lexpr]) and (val = reduce(compiler)).kind_of? ::Numeric
					@lexpr = nil
					@op = nil
					@rexpr = val
				end

				self
			end
		end
	end
end
end
